# coding=utf-8 # # Licensed to the Apache Software Foundation (ASF) under one # or more contributor license agreements. See the NOTICE file # distributed with this work for additional information # regarding copyright ownership. The ASF licenses this file # to you under the Apache License, Version 2.0 (the # "License"); you may not use this file except in compliance # with the License. You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, # software distributed under the License is distributed on an # "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY # KIND, either express or implied. See the License for the # specific language governing permissions and limitations # under the License. """ @file simple_logistic.py_in @brief Logistic Regression: Driver functions @namespace simple_logistic @brief Logistic Regression: Driver functions """ import plpy from utilities.validate_args import table_exists from utilities.validate_args import table_is_empty # ------------------------------------------------------------------------ def logregr_simple_train( schema_madlib, source_table, out_table, dependent_varname, independent_varname, max_iter=None, tolerance=None, verbose=None, **kwargs): """ Train logistic model @param schema_madlib Name of the MADlib schema, properly escaped/quoted @param source_table Name of relation containing the training data @param out_table Name of relation where model will be outputted @param dependent_varname Name of dependent column in training data (of type BOOLEAN) @param independent_varname Name of independent column in training data (of type DOUBLE PRECISION[]) @param max_iter The maximum number of iterations that are allowed. @param tolerance The precision that the results should have @param kwargs We allow the caller to specify additional arguments (all of which will be ignored though). The purpose of this is to allow the caller to unpack a dictionary whose element set is a superset of the required arguments by this function. @return A composite value which is __logregr_simple_result defined in simple_logistic.sql_in """ return __logregr_train_compute( schema_madlib, source_table, out_table, dependent_varname, independent_varname, max_iter, tolerance, verbose, **kwargs) # ======================================================================== def __logregr_train_compute(schema_madlib, tbl_source, tbl_output, dep_col, ind_col, max_iter, tolerance, verbose, **kwargs): """ Validate the arguments """ if tbl_source is None or tbl_source.strip().lower() in ('null', ''): plpy.error("Logregr error: Invalid data table name!") if not table_exists(tbl_source): plpy.error("Logregr error: Data table does not exist!") if table_is_empty(tbl_source): plpy.error("Logregr error: Data table is empty!") if tbl_output is None or tbl_output.strip().lower() in ('null', ''): plpy.error("Logregr error: Invalid output table name!") if not dep_col or dep_col.strip().lower() in ('null', ''): plpy.error("Logregr error: Invalid dependent column name!") # if not columns_exist_in_table(tbl_source, [dep_col]): # plpy.error("Logregr error: Dependent column does not exist!") if not ind_col or ind_col.lower() in ('null', ''): plpy.error("Logregr error: Invalid independent column name!") if max_iter <= 0: plpy.error("Logregr error: Maximum number of iterations must be positive!") if tolerance < 0: plpy.error("Logregr error: The tolerance cannot be negative!") update_plan = plpy.prepare( """ SELECT {schema_madlib}.__logregr_simple_step( ({dep_col})::boolean, ({ind_col})::double precision[], ($1)) FROM {tbl_source} """.format( tbl_output=tbl_output, schema_madlib=schema_madlib, dep_col=dep_col, ind_col=ind_col, tbl_source=tbl_source), ["double precision[]"]) state = None for it in range(0, max_iter): res_tuple = plpy.execute(update_plan, [state]) state = res_tuple[0].values()[0] output_table = plpy.prepare( """ drop table if exists {tbl_output}; create table {tbl_output} as select (result).coef as coef, (result).log_likelihood as log_likelihood from ( select * from {schema_madlib}.__logregr_simple_finalizer($1) ) result """.format(schema_madlib=schema_madlib, tbl_output=tbl_output), ["double precision[]"]) plpy.execute(output_table, [state]) return None # -------------------------------------------------------------------- def logregr_simple_help_msg(schema_madlib, message, **kwargs): """ Help message for logistic regression @param message A string, the help message indicator Returns: A string, contains the help message """ if not message: help_string = """ ---------------------------------------------------------------- SUMMARY ---------------------------------------------------------------- Binomial logistic regression models the relationship between a dichotomous dependent variable and one or more predictor variables. The dependent variable may be a Boolean value or a categorical variable that can be represented with a Boolean expression. For more details on function usage: SELECT {schema_madlib}.logregr_train('usage') For a small example on using the function: SELECT {schema_madlib}.logregr_train('example') """ elif message in ['usage', 'help', '?']: help_string = """ ------------------------------------------------------------------ USAGE ------------------------------------------------------------------ SELECT {schema_madlib}.logregr_train( source_table, -- name of input table out_table, -- name of output table dependent_varname, -- name of dependent variable independent_varname, -- names of independent variables max_iter, -- optional, default 20, maximum iteration number tolerance, -- optional, default 0.0001, the stopping threshold verbose -- optional, default FALSE, whether to print useful info ); ------------------------------------------------------------------ OUTPUT ------------------------------------------------------------------ The output table ('out_table' above) has the following columns: <...>, -- Grouping column values used during training 'coef', double precision[], -- vector of fitting coefficients 'log_likelihood', double precision, -- log likelihood 'std_err', double precision[], -- vector of standard errors of the fitting coefficients 'z_stats', double precision[], -- vector of the z-statistics of the coefficients 'p_values', double precision[], -- vector of the p values 'odds_ratios', double precision[], -- vector of odds ratios, exp(coefficients) 'condition_no', double precision, -- the condition number 'num_rows_processed', integer, -- how many rows are actually used in the computation 'num_missing_rows_skipped', integer, -- number of rows that contain NULL and were skipped per group 'num_iterations' double precision -- how many iterations are used in the computation per group """ elif message in ['example', 'examples']: help_string = """ CREATE TABLE patients( id INTEGER NOT NULL, second_attack BOOLEAN, treatment INTEGER, trait_anxiety INTEGER); COPY patients FROM STDIN WITH DELIMITER '|'; 1 | True | 1 | 70 3 | True | 1 | 50 5 | True | 0 | 40 7 | True | 0 | 75 9 | True | 0 | 70 11 | False | 1 | 65 13 | False | 1 | 45 15 | False | 1 | 40 17 | False | 0 | 55 19 | False | 0 | 50 2 | True | 1 | 80 4 | True | 0 | 60 6 | True | 0 | 65 8 | True | 0 | 80 10 | True | 0 | 60 12 | False | 1 | 50 14 | False | 1 | 35 16 | False | 1 | 50 18 | False | 0 | 45 20 | False | 0 | 60 \. -- Drop output tables before calling the function DROP TABLE IF EXISTS patients_logregr; DROP TABLE IF EXISTS patients_logregr_summary; SELECT madlib.logregr_simple_train( 'patients', 'patients_logregr', 'second_attack', 'ARRAY[1, treatment, trait_anxiety]'); SELECT * from patients_logregr; """ else: help_string = "No such option. Use {schema_madlib}.logregr_simple_train('help')" return help_string.format(schema_madlib=schema_madlib) # ------------------------------------------------------------------------